RelativeLane.java
package org.opentrafficsim.road.gtu.lane.perception;
import java.io.Serializable;
import org.djutils.exceptions.Throw;
import org.opentrafficsim.core.network.LateralDirectionality;
/**
* Defines a lane relative to the current lane.
* <p>
* Copyright (c) 2013-2020 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved. <br>
* BSD-style license. See <a href="http://opentrafficsim.org/docs/current/license.html">OpenTrafficSim License</a>.
* <p>
* @version $Revision$, $LastChangedDate$, by $Author$, initial version May 2, 2016 <br>
* @author <a href="http://www.transport.citg.tudelft.nl">Wouter Schakel</a>
*/
public class RelativeLane implements Comparable<RelativeLane>, Serializable
{
/** */
private static final long serialVersionUID = 20160502L;
/** Second left lane. */
public static final RelativeLane SECOND_LEFT = new RelativeLane(LateralDirectionality.LEFT, 2);
/** Left lane. */
public static final RelativeLane LEFT = new RelativeLane(LateralDirectionality.LEFT, 1);
/** Current lane. */
public static final RelativeLane CURRENT = new RelativeLane(LateralDirectionality.NONE, 0);
/** right lane. */
public static final RelativeLane RIGHT = new RelativeLane(LateralDirectionality.RIGHT, 1);
/** Second right lane. */
public static final RelativeLane SECOND_RIGHT = new RelativeLane(LateralDirectionality.RIGHT, 2);
/**
* Rank, summarizes both the lateral directionality and the number of lanes. Is zero for CURRENT, otherwise equal to number
* of lanes for RIGHT, negative number of lanes for LEFT.
*/
private final int rank;
/**
* Private constructor.
* @param rank int; the rank
*/
private RelativeLane(final int rank)
{
this.rank = rank;
}
/**
* Constructor.
* @param lat LateralDirectionality; lateral direction (use {@code null} for the current lane)
* @param numLanes int; number of lanes in the lateral direction (not important for the current lane)
* @throws IllegalArgumentException if numLanes is not at least 1, except if {@code lat == null} (current lane)
* @throws IllegalArgumentException if numLanes is not 0 if {@code lat == null} (current lane)
*/
public RelativeLane(final LateralDirectionality lat, final int numLanes)
{
Throw.whenNull(lat, "Lateral directionality may not be null.");
Throw.when(lat.isNone() && numLanes != 0, IllegalArgumentException.class,
"Number of lanes must be zero if the lateral directionality is NONE.");
Throw.when((!lat.isNone()) && numLanes <= 0, IllegalArgumentException.class,
"Relative lane with %d lanes in %s direction is not allowed, use values > 0.", numLanes, lat);
this.rank = lat.isLeft() ? -numLanes : numLanes;
}
/**
* Returns the lateral direction.
* @return LateralDirectionality; the lateral direction
*/
public final LateralDirectionality getLateralDirectionality()
{
// return this.lat;
return this.rank == 0 ? LateralDirectionality.NONE
: this.rank < 0 ? LateralDirectionality.LEFT : LateralDirectionality.RIGHT;
}
/**
* Returns the number of lanes in the lateral direction.
* @return int; number of lanes in the lateral direction
*/
public final int getNumLanes()
{
return Math.abs(this.rank);
}
/**
* Returns whether the second left lane is referred to.
* @return whether the second left lane is referred to
*/
public final boolean isSecondLeft()
{
return this.equals(SECOND_LEFT);
}
/**
* Returns whether the left lane is referred to.
* @return whether the left lane is referred to
*/
public final boolean isLeft()
{
return this.equals(LEFT);
}
/**
* Returns whether the current lane is referred to.
* @return whether the current lane is referred to
*/
public final boolean isCurrent()
{
return this.equals(CURRENT);
}
/**
* Returns whether the right lane is referred to.
* @return whether the right lane is referred to
*/
public final boolean isRight()
{
return this.equals(RIGHT);
}
/**
* Returns whether the second right lane is referred to.
* @return whether the second right lane is referred to
*/
public final boolean isSecondRight()
{
return this.equals(SECOND_RIGHT);
}
/**
* Returns the left hand relative lane of this relative lane.
* @return left hand relative lane of this relative lane.
*/
public final RelativeLane getLeft()
{
return this.add(LEFT);
}
/**
* Returns the right hand relative lane of this relative lane.
* @return right hand relative lane of this relative lane.
*/
public final RelativeLane getRight()
{
return this.add(RIGHT);
}
/**
* Returns the relative lane relative to this lane, for example "the left lane" of "the 3rd right lane" is "the 2nd right
* lane".
* @param relativeLane RelativeLane; relative lane to get of this lane
* @return relative lane relative to this lane
*/
public final RelativeLane add(final RelativeLane relativeLane)
{
return new RelativeLane(this.rank + relativeLane.rank);
}
/** {@inheritDoc} */
@Override
public int hashCode()
{
final int prime = 31;
int result = 1;
result = prime * result + this.rank;
return result;
}
/** {@inheritDoc} */
@Override
public boolean equals(final Object obj)
{
if (this == obj)
{
return true;
}
if (obj == null)
{
return false;
}
if (getClass() != obj.getClass())
{
return false;
}
RelativeLane other = (RelativeLane) obj;
if (this.rank != other.rank) // relative lane is uniquely defined by the rank
{
return false;
}
return true;
}
/** {@inheritDoc} */
@Override
public final String toString()
{
if (this.equals(CURRENT))
{
return "RelativeLane [CURRENT]";
}
return new StringBuilder("RelativeLane [").append(getLateralDirectionality()).append(", ").append(getNumLanes())
.append("]").toString();
}
/** {@inheritDoc} */
@Override
public final int compareTo(final RelativeLane rel)
{
return this.rank - rel.rank;
}
}